Balancing Reaction Equations Oxidation State Reduction-oxidation Reactions · 2018. 1. 11. · Fe...
Transcript of Balancing Reaction Equations Oxidation State Reduction-oxidation Reactions · 2018. 1. 11. · Fe...
1
Balancing Reaction Equations Oxidation State
Reduction-oxidation Reactions
OCN 623 – Chemical Oceanography
Chemistry is the glue that holds together all the other fields of oceanography
Chemistry interacts directly with each of the other fields
Chemical distributions in the ocean secretly record and integrate the biological, physical and geological processes
There are 118 chemical elements many with multiple oxidation states and isotopes—lots of tracers to investigate the world
2
Balanced chemical reactions are the math of chemistry
They show the relationship between the reactants and the products
We will use thermodynamics later on to calculate the feasibility of reactions and to understand how equilibrium is established
The concept of equilibrium allows us to understand chemical processes such as ionic speciation, oxidation state distributions gas solubility, the carbonate system ……
Elements are electrically neutral, the number of protons in the nucleus exactly balances the number of electrons that fill the shells
Shells are filled in order with each additional electron occupying the lowest energy shell available
3
f orbitals
4
A. Oxidation state or number
Oxidation: Loss of electrons from an element. Oxidation number increases
Reduction: Gain of electrons by an element. Oxidation number decreases
If we want to determine whether reaction is oxidation or reduction Need to know oxidation number of the element and how it changes
Rules for determining oxidation number of an element
1. Oxidation state of an element in its elementary state = 0
e.g. Cl2, Na, P,….etc.
2. Oxidation state of an element in a monatomic (only one atom) ion is equal to the charge on the ion
e.g. Na+= +1; Cl- = -1; Fe3+ = +3
5
3. Oxidation state of certain elements is the same in all, or almost all of their compounds e.g. Group 1A elements: Li, Na, K, Rb, Cs =+1
Group 2A elements: Be, Mg, Ca, Sr, Ba, Ra = +2 Group VII b elements: F, Cl, Br, I, At = -1 in binary compounds Oxygen is almost always -2 (Except: when bonded to O or F) H is almost always +1; Except with a metal, e.g. NaH, CaH2
is -1
4. The sum of the oxidation states in a neutral species is = 0; In a charged ion it is equal to the charge on the ion e.g. Na2Se: Na = +1x2 = 2, thus Se = -2 MnO4
- : O= -2x4 = -8, thus Mn =8-1 = 7
6
5. Fractional oxidation numbers are possible. E.g., in Na2S4O6 (sodium tetrathionate), S has an oxidation number of +10/4:
O: 6(-2) = -12
Na: 2(+1) = 2
Residual = -10, which must be balanced by S:
S: 4(+10/4) = +10
6. The oxidation number is designated by:
• Arabic number below the atom, or
• Roman numeral or Arabic number after the atom (in parentheses)
What is the oxidation state of the elements in KNO3? K= ?; O= ?; N=? K2Cr2O7? K= ?; O= ?, Cr= ?
Oxidation is an increase in oxidation state e.g. Cl- to Cl2 is -1 to 0 Reduction is a decrease in oxidation state SO4
2- to H2S is a reduction S VI to S -II Recognising oxidation/reduction KMnO4
to MnO2 oxidation or reduction?
7
B. Balancing oxidation-reduction reactions
Conventionally always put the oxidised species on the left, the reduced species on the right
1. Separate the reaction into a reduction and oxidation part MnO4
- (aq)
= Mn2+(aq) reduction
Cl-(aq) = Cl2(g) oxidation
2. Balance each 1/2 reaction with respect to mass then with respect to charge. Use e-, H+, H2O or OH-
2Cl-(aq) = Cl2 (g) mass 2Cl-(aq) = Cl2 (g) + 2e- mass + charge A
e.g. MnO4-
(aq) + Cl-(aq) = Mn2+
(aq) + Cl2(g)
MnO4-(aq) = Mn2+
(aq) + 4H2O (mass oxygen) MnO4
-(aq) + 8H+ = Mn2+
(aq) + 4H2O (mass oxygen+ hydrogen) MnO4
-(aq) + 8H+ + 5e- = Mn2+
(aq) + 4H2O (mass + charge) B
3. Combine half reactions so electron gain equals loss
5*A = 10 e-; 2*B = 10 e- i.e. 5*A +2*B 10 Cl-(aq) + 2MnO4
- + 16H+ = 5Cl2(g) + 2Mn2+
(aq) +8H2O 4. Check for atom and charge balance
8
C. Oxidation of organic matter
CH2O + SO42- + H2O = CO2 + H2S
0 IV ox state of C
How did we get the oxidation state of the C in CH2O?
Separate into oxidation and reduction half reactions
SO42- + 8e-+10 H+ = H2S + 4H2O A
CH2O + H2O = CO2 + 4H+ + 4 e- B
Combine so electrons balance: A + B*2 2 CH2O + SO4
2- +2 H2O + 10H+ = H2S + 4 H2O + 2 CO2 + 8 H+ Simplify by subtracting 8 H+ and 2 H2O from each side.
2 CH2O + SO42- + 2H+ = H2S + 2 H2O + 2 CO2
This reaction is the oxidation of organic matter through the reduction of sulphate, you will see this reaction later in reducing sediments.
9
I- + MnO4- = I2 + MnO2
Oxidation: 2I- = I2 + 2e- A Reduction: MnO4
- + 4H+ +3e- = MnO2 + 2H2O remove H+ by adding OH- to each side * 4 (4H+ + 4OH- = 4 H2O) MnO4
- + 4 H2O+ +3e- = MnO2 + 2H2O + 4OH-
simplify: MnO4- + 2 H2O +3e- = MnO2 + 4OH- B
combine so electrons balance: A * 3 + B * 2 6I-+ 2MnO4
- + 4H2O = 3I2 + 2MnO2 + 8OH-
D. An example in basic solution:
E. A weathering reaction. Fe2SiO4 + O2 = Fe2O3 + FeSiO3 II III II ox state of Fe i.e. Fe is oxidised Iron Olivine = Haemetite + Ferrosilite ( Fe pyroxene) Separate and balance for mass and charge
O2 + 4 e - = 2O2- reduction A 2Fe2SiO4 + H2O = Fe2O3 + 2e- + 2FeSiO3 + 2H+ oxidation B Note have added H2O on LH side Combine eqns balancing e- A+ 2*B 4Fe2SiO4+ 2H2O+O2+4 e- = 2Fe2O3+ 4e-+4FeSiO3+4H+ +2O2- cancel 4e- on each side then cancel as 2H2O = 4H+ + 2O2- 4Fe2SiO4 + O2 = 2Fe2O3 + 4FeSiO3 Removal of oxygen by oxidation of reduced iron compounds
10
Example where the same compound is being oxidised and reduced: Cl2 + H2O = HOCl + H+ + Cl- Cl2 + 2e- = 2Cl- (reduction of Cl) Cl2 + 2H2O = 2 HOCl + 2H+ + 2e- (oxidation of Cl) 2Cl2 + 2H2O = 2 HOCl + 2H+ + 2 Cl- This may have been what happened to Cl2 released from the degassing of the early Earth.
The Periodic table
https://youtu.be/VgVQKCcfwnU
11
Rejected elements of the periodic table